SE517104C2 - Device for fixing a pipe means - Google Patents

Abstract

A device for fixing a tube member in a cavity of a patient. The device includes a body that surrounds the tube member and has a casing that at least partly forms an inner space. The body is expandable by supplying a fluid to the inner space in such a way that the fluid in the inner space has a working pressure. Furthermore, the body has, in a non-expanded state, a relatively small outer extent, which permits the introduction into said cavity, and in an expanded state, a relatively large outer extend, which permits fixing in said cavity by abutment with a contact pressure against a tubular wall of the cavity. In order to ensure a tight abutment against the wall of the cavity, the body has such a geometrical shape that the contact pressure is substantially constant independent of variations of the working pressure within a normal working range.

Description

25 30 35. . . . .s 517 104 Such an obstruction, which can occur if the abutment pressure of the fixing member is too great, can quickly have serious consequences through focal tissue death.

It is now known to use inflatable balloons as fixing means, which in the inflated state are to be pressed against the wall of the cavity, and thus fix the tubular means in the cavity and at the same time provide a good seal. The inflatable balloons currently used have problems with - only on both leakage and tissue damage.

Such leakage can be very serious, for example in connection with respirator treatment using the above-mentioned endotracheal tube. If leakage occurs, contaminated secretions from the upper respiratory tract can leak past the balloon down to the sterile lungs and cause pneumonia. In such treatment, pressure damage to the mucosal tissue is also very common when using such balloons.

The thin-walled rubber / plastic materials used in the casing housing are permeable. It is thus difficult to maintain a consistent working pressure in the balloon. Gas diffuses out, which lowers the pressure and increases the risk of leakage. The situation is the opposite when using certain anesthetic gases, which contain nitric oxide, where the gas goes in the opposite direction and the working pressure inside the balloon gradually increases with the attendant risk of pressure damage to the tissue.

Such a conventional balloon, seen in a longitudinal sectional view, has a shape which is round, oblong or oval. This means that a change in working pressure inside the balloon results in a corresponding change in the external installation pressure that is applied to the wall of the cavity.

Furthermore, these known balloons in a freely inflated state have a minimum given range. Is the inner circumference of the cavity which the balloon is to seal against smaller small axial folds formed on the abutment surface of the balloon. Such folds lead to leakage and can also be irritating to the tissue. Even with a moderate rotational movement of the balloon in relation to the wall of the cavity, creasing can occur.

SUMMARY OF THE INVENTION The object of the present invention is to eliminate the above-mentioned problems and to provide a fixing device which ensures a good sealing function and at the same time minimizes the risk of pressure damage to the tissue against which the fixing device is to rest.

This object is achieved with the initially defined device which is characterized in that the body has such a geometric shape that said abutment pressure is substantially constant independent of variations of said working pressure within a normal working range. With such a design, the abutment pressure will be provided by the geometric or structural shape of the body rather than by the working pressure prevailing in the interior space. This is a very important advance because the internal working pressure will vary during the use of the fixing device due to the above-mentioned problems of gas diffusing into and out of the internal space, that the body moves in different directions relative to the cavity wall and that the size of the cavity can vary over time. The working pressure variations that occur due to these causes are all within the normal working range. The present invention thus provides a fixing device which has an improved sealing function in situations with non-dimensional cavities and where external movements give an unfavorable force effect.

At the same time, thanks to the essentially constant contact pressure, the risk of pressure damage in various organic applications can be reduced. 10 15 20 25 30 35 - ~. According to an embodiment of the invention, in the expanded state the body is arranged to form an abutment surface at the outer circumference, which is arranged to abut against said wall.

In this case, the housing can advantageously comprise at least a section which extends inwards into the inner space and which allows an elastic displacement of the abutment surface in the direction towards and from said wall. With such a section, a substantially constant contact pressure can thus be achieved. Advantageously, said section extends around the pipe member.

According to a further embodiment of the invention, the body has at least in the expanded state along the pipe member a relatively long extent in the vicinity of the outer circumference and a relatively short extent in the vicinity of the pipe member. Such a body extending outwards from the pipe member has a great deal of flexibility and allows dense continuous abutment at different radii of the cavity. Due to the shorter internal extent, the diameter of the outer circumference of the body can vary with essentially the same abutment pressure. Furthermore, the contact pressure can be kept constant if the working pressure increases or decreases because the length of the short extension can vary. The shorter extension also allows the abutment surface to be inclined inwards or outwards towards a center axis through the pipe member, either at the same angle along the entire abutment surface or with different angles for different sections. The fixing device according to the invention is thus very suitable for cavities where the cavity wall does not have a linear extent.

According to a further embodiment of the invention, the abutment surface along the pipe member is longer than said short extent. With such an abutment surface which is longer than the extent of the body in the vicinity of the pipe member, a good seal against the cavity wall allows. In this case, the abutment surface can advantageously comprise a first circumferential surface portion and a second circumferential surface portion, these surface portions being separated from each other by a circumferential depression. With such a division -. . ~ - a. 10 15 20 25 30 35. . a. .s 517 104 of the abutment surface in two portions further increases the flexibility of the body. In this case, for example, one surface portion can abut against the cavity wall along a different extent than the extent to which the other surface portion abuts. When the device according to the invention together with the pipe member is inserted into the cavity and expanded, the geometric shape which the body would have assumed in a freely expanded state will be deformed when it meets resistance to the limiting wall of the cavity. However, the body will try to regain its original shape.

By the design of reduced portions, i.e. said short extent and in some cases also said depression, one can obtain a desired size of the flexural resistance which one wishes to obtain. The flexural resistance is the abutment pressure that is transmitted to the walls of the cavity and it is for a given design relatively constant at different degrees of flexion. With the design according to the invention, the working pressure in the inner space will instead be varied due to external influences without the abutment pressure against the cavity wall being changed for that purpose. The reduced parts will also take over the tendency to crease that exists in such an expandable body, which means that the contact surface will in principle lack substantially all creases.

The geometric shape of the body also contributes to the fact that a direct external axial force on the housing will be transmitted to the walls of the cavity in a way that contributes to increased safety against leakage. During relief, the pressure against the wall is normalized again and such intermittent loading and unloading can in certain organic contexts give a favorable "pulsation" which stimulates the blood supply to the peripheral tissue. Advantageously, the circumferential recess is designed in such a way that it does not abut against said wall in the expanded state.

According to a further embodiment of the invention, the casing is made of a flexible material. In this case, the cover can be designed in such a way that the length of said short extent in the ex- -. The condition is variable depending on the diameter of the body with respect to the external range and / or the relationship between said working pressure and an ambient pressure. Advantageously, the housing is also made of an elastic material. The casing may have a thickness which is substantially uniform and be preformed in such a way that it at least partially exhibits said geometric shape in a state of rest, i.e. a free state when the internal pressure is substantially equal to the external ambient pressure and the body is not inserted in any cavity with limiting wall.

According to a further embodiment of the invention, the casing is fixedly connected to the pipe member. In this case, the casing may comprise a first end portion which is fixedly connected to the pipe member and a second end portion which is fixedly connected to the pipe member, the pipe member between the two end portions forming a limitation of the inner space. It is also possible to design the casing in such a way that it itself completely encloses the inner space. In this case, the body as a whole can be moved on and also moved along a pipe member for adapting the position of the body on the pipe member.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be explained in more detail by way of description of various embodiments and with reference to the accompanying drawings.

Fig. 1 shows a partially sectioned view of a device according to the invention in an expanded free state.

Fig. 2 shows a partially sectioned view of the device of Fig. 1 inserted into a cavity with a first diameter.

Fig. 3 shows a partially sectioned view of the device of Fig. 1 inserted into a cavity with a second diameter. 10 15 20 25 30 35. . Fig. 417 104 Fig. 4 shows a partially sectioned view of the device in Fig. 1 inserted into a cavity with a third diameter.

Figs. 5-7 show a sectional view of the device of Fig. 1 in different states.

Fig. 8 shows a view of the device of Fig. 1 inserted into a curved cavity.

Fig. 9 shows a view of the device in Fig. 1 subjected to rotating movements.

Fig. 10 shows a sectional view of a device according to another embodiment of the invention.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS OF THE INVENTION Figures 1-9 show an embodiment of a device for fixing a tubular member 1 in a cavity 2 of a patient. Fig. 1 shows the device in a freely expanded state, i.e. the device is not inserted into any cavity 2. The device comprises a body 3 which is arranged to surround the pipe member 1. The body 3 is hollow and comprises a housing 4 which thus at least partially encloses an inner space 5. In the embodiment shown, the inner space 5 is formed by the housing 4 and a section of the outer surface of the pipe member 1. It is also conceivable, within the scope of the invention, to allow the housing 4 to completely enclose the inner space 5, the body 3 being applied to the pipe member 1 in such a way that a part of the housing 4 abuts against the outer surface of the pipe member 1. According to these embodiments, the housing 4 can be fixedly connected to the pipe member 1, for example by a permanent connection such as gluing, melting, or shrinkage, ie by the housing 4 being tensioned around the pipe member 1. The housing 4 is flexible and made of an elastic rubber-like material . Advantageously, the housing 4 has a thickness which is substantially uniform around the inner space 5. Q n u. 517 104 The pipe member 1 may be substantially straight, as indicated in Figs. 1-7 and 9, or have a curved extent as indicated in Fig. 8.

The pipe member comprises a center axis x which can thus also be straight or have a certain curvature. The center axis x also forms the center axis of the body 3. The device is shown in Figs. 1-4 partially sectioned along the center axis x and in Figs. 5-7 fully sectioned along the center axis x.

The body 3 is expandable by supplying a fluid to the inner space 5 via a supply line 6. The fluid can be a gas, a liquid or a foam. The supply line 6 is shown only in Fig. 1 for simplicity. Thus, the body 3 may be in an unexpanded state, the fluid being substantially sucked out of the interior space 5. The body may also be in an expanded state, as shown in Figs. 1-9, with the fluid being supplied so that there is a working pressure in the inner space 5. In the non-expanded state the body 3 has a relatively small radial outer circumference, which allows insertion into the cavity 2. In the expanded state the body 3 has a relatively large radial outer circumference scope, which allows fixation of the body 3 in said cavity 2 by the body 3 being pressed against a tubular inner wall 7 which at least partially defines the cavity 2. Thereby the body 3 has an abutment surface which abuts against the wall 7. In the embodiment shown the abutment surface has two separate surface portions 8 and 9, which are separated from each other by a circumferential depression or groove 10 which extends around the pipe member 1 and inwards into the inner space 5.

The body 3 has such a geometric shape and structure that the abutment pressure with which the surface portions 8 and 9 abut against the wall 7 is substantially constant independent of variations of the working pressure in the inner space 5 within a normal working range, i.e. normal variations in the working pressure which can be between 10 and 30 mmHg. Such normal variations in the working pressure occur due to diffusion of gas into and out of the inner space 5, movements of the body 3 relative to the cavity 2 10 15 20 25 30 35 - | - Q .- 517 104 - - - u a u. Wall 7 and normal size variations of the cavity 2 over time. The geometric shape of the body 3 is thus structurally conditioned or preformed in connection with the manufacture of the device. The body 3 will thus have this preformed geometry in a state of rest, i.e. when substantially the same pressure prevails outside the housing 4 as in the inner space 5. Even in the free state shown in Fig. 1, the body 3 has this preformed geometry. meters.

As is clear from Figs. 2-4, the body 3 in the expanded state along the pipe member 1 and the center axis x has a relatively long axial extent in the vicinity of the outer circumference and a relatively axial extent in the vicinity of the pipe member 1. More specifically, the abutment surface, together with the recess 10 between the surface portions 8 and 9, a longer axial extent than the body 3 in the vicinity of the pipe member 1. In this way a section 11 is formed which extends around the pipe member 1 and inwards into the inner space 5 of the body 3 in the proximity of the pipe member 1 when the body 3 is viewed in the longitudinal section. In Fig. 2, the cavity 2 has a relatively large inner diameter d, i.e. a relatively large diameter between opposite wall surfaces of the wall 7. Thereby, the shorter extent of the body 3 has a greater length than the corresponding short extent of the body 3 when said diameter d is shorter, as shown in Figs. 3 and 4 in comparison with Fig. 2.

At the same time, the length of the body 3 increases at the radially outer circumference when said diameter d decreases. At the same time, the depression 10 will decrease in size as the above-mentioned diameter d decreases. Thanks to these flexion points, i.e. sections 11 and 10 of the body 3, the abutment pressure against the wall 7 of the cavity 2 will be substantially equal regardless of the length of said diameter d.

Fig. 5 shows schematically by means of arrows the abutment force in different positions of the surface portions 8 and 9 when the body 3 is in a normally expanded state without any significant influence from external forces. 10 15 20 25 30 35 517 104 10 In Fig. 6 there is a higher pressure to the right of the device than to the left of the same. As a result, the waist on the right side of the body 3 will be pressed inward, which causes. that the abutment force against the wall 7 from the surface portion 9 decreases while the abutment force of the surface portion 8 increases slightly. In the same way, a slightly greater abutment force of the surface portion 9 is obtained than the surface portion 8 if the pressure is higher to the left of the device than to the right of the same, as shown in Fig. 7.

Fig. 8 illustrates how the two surface portions 8 and 9 maintain their tight abutment against the wall 7 with a substantially even abutment pressure even if the wall 7 is slightly curved in the direction x of the shaft while preventing creasing of the surface portions 8 and 9. The folding or creasing takes place in the recess 10 which is not in contact with the wall 7.

Correspondingly, an even abutment pressure of the surface portions 8 and 9 can be maintained even if the two surface portions 8 are exposed to rotating forces in the opposite direction while creasing of the surface portions 8 and 9 is prevented. The folding or creasing takes place in the recess 10 which is not in contact with the wall 7.

Fig. 10 shows another embodiment of the invention, according to which the body 3 has a relatively long extension in the vicinity of the pipe member 1 and a shorter extension at the outer circumference and at the abutment surface. According to this embodiment, the casing 4 of the body 3 comprises two sections 12 extending around the tubular member 1 and inwards into the inner space 5. Thanks to these sections 12, or flexion points, the surface portions 8 and 9 of the abutment surface can be resilient, resilient means are displaced inwards from the wall 7 or outwards towards the wall 7, i.e. in radial direction with respect to the center axis x, in such a way that a substantially constant abutment pressure is maintained independent of the radial position of the abutment surface and independent of the working pressure in the interior space 5 . ~ -. - .- 517 104 ~. -. 11.

The invention is not limited to the embodiment shown but can be varied and modified within the scope of the appended claims.

Claims (14)

10 15 20 25 30 35 517 104 12 Patent claims A device for fixing a tubular member (1) in a cavity (2) of a patient, the device comprising a body (3), which is arranged to surround the tubular member (1) and has a housing (4) which at least partially forms an inner space (5), the body (3) being expandable by supplying a fluid to the inner space (5) in such a way that the fluid in the inner space has a working pressure and wherein the body (3) in an unexpanded state has a relatively small outer circumference which allows insertion into said cavity (2) and in an expanded state has a relatively large outer circumference which allows fixation in said cavity (2) by abutment with an abutment pressure against a tubular wall (7) of the cavity, characterized in that the body (3) has at least in the expanded state along the pipe member (1) a relatively long extent in the vicinity of the outer circumference and a relatively short extent in the vicinity of the pipe member (1), the body (3) having such a geometric shape to mention the abutment pressure is substantially constant independent of variations of said working pressure within a normal working range. Device according to claim 1, characterized in that the body (3) in the expanded state is arranged to form an abutment surface (8, 9) at the outer circumference, which is arranged to abut against said wall (7). Device according to claim 2, characterized in that the housing (4) comprises at least one section (10, 11, 12) which extends inwards into the inner space (2) and which allows an elastic displacement of the abutment surface in the direction of and from said wall (7). Device according to claim 3, characterized in that said section (10, 11, 12) is designed to extend around the pipe member (1). 10 15 20 25 30 35 517 104 13 -.n a; Device according to any one of the preceding claims, characterized in that the abutment surface (8, 9) along the pipe member (1) is longer than said short extent. Device according to claim 5, characterized in that the abutment surface comprises a first circumferential surface portion (8) and a second circumferential surface portion (9), these surface portions being separated from each other by a circumferential depression (10). Device according to claim 6, characterized in that the circumferential recess (10) is designed in such a way that it does not abut against said wall (7) in the expanded state. Device according to one of the preceding claims, characterized in that the housing (4) is made of a flexible material. Device according to claim 8, characterized in that the housing (4) is designed in such a way that the length of said short extent in the expanded state is variable depending on the diameter of the body (3) with respect to the outer circumference and / or the ratio between said working pressure and an ambient pressure. Device according to one of the preceding claims, characterized in that the housing (4) is made of an elastic material. Device according to one of the preceding claims, characterized in that the housing (4) has a thickness which is substantially uniform. Device according to one of the preceding claims, characterized in that the housing (4) is preformed so that it at least partially has said geometric shape in a state of rest. Device according to one of the preceding claims, characterized in that the housing (4) is fixedly connected to the pipe member (1). 517 104 14 Device according to one of the preceding claims, characterized in that the housing (4) comprises a first end portion which is fixedly connected to the pipe member (1) and a second end portion which is fixedly connected to the pipe member (1), the pipe member (1) ) between the two end portions forms a boundary of the inner space (5).